DE102013201906A1 - High pressure pump with integrated differential pressure valve - Google Patents

Abstract

A housing (30) for a high-pressure pump (12) for delivering fuel comprises a pump chamber (28) inside the housing (30), in which the fuel is compressed, and a differential pressure valve (26) with a piston (48) which is received in a valve carrier of the differential pressure valve (26). The differential pressure valve (26) is designed to connect a valve inlet (34) to a valve outlet (38) when the piston (48) is subjected to a predetermined pressure. The valve carrier is designed as a bore (32) in the housing (30).

Description

Field of the invention

The invention relates to a housing for a high pressure pump, a high pressure pump and a fuel delivery system.

Background of the invention

High-pressure diesel pumps, which supply high-pressure fuel to common-rail injection systems, include an overflow or differential pressure valve that is threaded into the housing of the high-pressure pump.

Such a differential pressure valve is usually screwed into the housing and provides a connection between the low pressure circuit of the high pressure pump and a pump return. The differential pressure valve is used to limit the pump interior to the pump return to a certain pressure level and to lead an excess quantity in the pump return or in a tank. The differential pressure valve ensures a defined interior pressure and can thus ensure the forced lubrication of the bearings and the filling pressure.

A differential pressure valve comprises, for example, a valve carrier, which is designed as a sleeve, and a piston, a compression spring and a plug, which are accommodated in the sleeve. The spring-loaded piston moves in the sleeve and limits the pump interior pressure via its control edge and the drain holes in the valve carrier.

Summary of the invention

It is an object of the invention to simplify the construction of a high pressure pump with differential pressure valve.

This object is solved by the subject matter of the independent claims. Further embodiments of the invention will become apparent from the dependent claims and from the following description.

One aspect of the invention relates to a housing for a high pressure pump for delivering fuel. The housing may be made of metal, for example, for example, from a cast blank, which is reworked.

According to one embodiment of the invention, the housing comprises a pump space inside the housing in which the fuel is compressed and a differential pressure valve with a piston which is accommodated in a valve carrier of the differential pressure valve. The differential pressure valve is adapted to connect a valve inlet to a valve outlet when the piston is pressurized to a predetermined pressure. The valve outlet is usually connected to a return line in the direction of a tank. The valve inlet is usually connected to the pump chamber, for example via a further bore in the housing. In this way, open at a correspondingly high internal pressure in the pump chamber, the differential pressure valve and compensate for the internal pressure. The differential pressure valve may be, for example, a pressure relief valve.

The valve carrier is designed as a bore in the housing. In this way, a costly separate valve carrier (for example in the form of a metal sleeve), a sealing plug, a locking plate and a stop disc can be omitted. In addition, the processing cost of the pump housing can be additionally reduced.

It should be understood that a bore may be a hole in the housing of substantially circular cross-section. For example, the hole may already be provided during the casting of the housing. Also, the bore can be created by machining the housing.

In any case, the valve carrier may be formed of the material of the housing, i. the piston is received directly in the housing or guided directly in the bore.

According to one embodiment of the invention, the housing has at least one connection bore which connects the valve inlet to the valve outlet. The connection bore may be (substantially) parallel to the valve support bore. In a closed position, the piston can close the communication bore so that no fuel can get out of the valve port into the valve port. In an open position, the piston can release the connection bore.

The housing may have a plurality of connection bores arranged around the valve support bore.

According to one embodiment of the invention, the connection bore is connected via a return bore to the valve carrier bore. The connection bore need not be connected directly to the valve carrier bore, but may be connected via a further bore and / or groove with the valve carrier bore.

The return bore, for example, a flange bearing return or a housing bearing return be. The return bore may be oblique or substantially orthogonal to the valve support bore and / or may pierce the valve support bore such that a plurality of connection bores are simultaneously connected to the valve support bore.

A control edge of the differential pressure valve may be part of an opening in the wall of the valve support bore which is closed by the piston in a closed position of the piston and is released in a (fully) open position of the piston. The opening area of the opening in an intermediate position of the piston between the closed position and the open position may be adjusted by the shape of the control edge (which is, for example, an edge of the opening).

For example, a return bore extending through the valve support bore may provide this opening.

According to one embodiment of the invention, the control edge of the differential pressure valve is formed by an undercut in the valve carrier bore. The undercut may provide a connection to the connection hole (s). An undercut may be a portion in the valve support bore that has a larger diameter than an outer diameter of the piston.

According to one embodiment of the invention, the undercut comprises an annular groove which surrounds the valve support bore at least in sections. The control edge can be executed with an undercut or undercut, for example in the form of a groove around the piston bore, with which a characteristic curve of the differential pressure valve can be selectively changed. The control edge or the undercut is made directly in the housing.

The annular groove may have an obliquely to the valve carrier bore extending side wall. The annular groove may be segmented circumferentially around the valve carrier bore. The annular groove can run obliquely to the valve carrier bore. The shape of the characteristic can be influenced by varying the groove depth, the groove geometry and / or the circumferential geometry.

According to one embodiment of the invention, the valve outlet is formed as a bore which is designed coaxially with the bore to the valve carrier. This hole can be a return pipe, in which a pipe can be accommodated with a connecting piece.

According to one embodiment of the invention, the housing further comprises a spring and a spring plate, wherein the spring is supported at one end on the valve piston and on another side on the spring plate. The spring serves to move the piston against the fuel pressure in the direction of the valve inlet, so that the piston covers the control edge and thus the connection bore to the valve outlet at too low pressure. By means of the spring characteristic, a characteristic curve for the pump interior pressure can be adapted.

According to one embodiment of the invention, the spring plate is received at the end of a bore for the valve outlet (for example, in the return pipe). The spring plate, which may be disc-shaped, thereby closes the spring chamber in front of the valve outlet. Since the bore for the valve outlet generally has a larger diameter than the valve carrier bore, a support surface is formed in this way, on which the spring plate is stored.

According to one embodiment of the invention, the spring plate is clamped by a recorded in the valve outlet spigot on the valve carrier bore. A tolerance advantage can result from the clamping of the spring plate by the low-pressure connection piece to the support surface perpendicular to the piston guide, since the machining takes place in a clamping position.

According to one embodiment of the invention, the spring plate has a throttle opening which connects the valve outlet with a spring chamber. Also, the piston may have a throttle opening which connects the spring chamber with the valve inlet. The two throttle openings may extend axially to the valve carrier bore.

Further, the spring plate holes, for example, in the circumferential direction extending slots, which provide a connection between the valve inlet and the or the connecting holes.

According to one embodiment of the invention, the piston is designed as a hollow cylinder with a center wall. In the middle wall may be located a throttle opening. A hollow piston on both sides can result in a weight saving of approx. 70%. A central force application (the spring on the center wall) can reduce the misalignment of the piston and can result in smooth movement of the piston. Also, the length of the differential pressure valve can be reduced by about 25% or more.

A further aspect of the invention relates to a high-pressure pump with a housing, as described above and below. In addition to the differential pressure valve can Housing still other components of the high-pressure pump, such as other valves, connections, pump piston, etc. record.

A further aspect of the invention relates to a fuel delivery system for a vehicle, such as a car, truck or bus.

The fuel delivery system includes a tank, a high pressure pump as described above and below, and a common rail injection system (also called a storage injection system). The high-pressure pump is designed to deliver fuel from the tank and fed to the common-rail injection system compressed. The differential pressure valve of the high pressure pump can redirect excess fuel into the tank.

In summary, the differential pressure valve is fully integrated into the housing. The functions of the differential pressure valve, such as piston guide, a valve control edge and / or a low pressure guide are directly implemented by the pump housing. A damped spring chamber can still be preserved.

Brief description of the figures

Embodiments of the invention will now be described in detail with reference to the accompanying drawings.

1 schematically shows a fuel distribution system according to an embodiment of the invention.

2 shows a three-dimensional view of a pump housing according to an embodiment of the invention.

3 shows a different three-dimensional view of the pump housing 2 ,

4 shows a different three-dimensional view of the pump housing 2 ,

5 shows a three-dimensional view of valve components for a pump housing according to an embodiment of the invention.

6 shows a three-dimensional view of a spring plate for a pump housing according to an embodiment of the invention.

7 shows a three-dimensional view of a piston for a pump housing according to an embodiment of the invention.

8th shows a three-dimensional view of a pump housing according to an embodiment of the invention.

9 shows a different three-dimensional view of the pump housing 8th ,

10 shows a different three-dimensional view of the pump housing 8th ,

11 schematically shows a valve support bore for a pump housing according to an embodiment of the invention.

12 schematically shows a valve support bore for a pump housing according to an embodiment of the invention.

13 schematically shows a valve support bore for a pump housing according to an embodiment of the invention.

14 schematically shows a valve support bore for a pump housing according to an embodiment of the invention.

15 schematically shows a valve support bore for a pump housing according to an embodiment of the invention.

Basically, identical or similar parts are provided with the same reference numerals.

Detailed description of embodiments

1 shows a fuel distribution system 10 that is a high pressure pump 12 which has fuel from a fuel tank 14 in a common-rail injection system 16 promotes. The fuel distribution system 10 For example, it can be installed in a vehicle with a diesel engine.

The high pressure pump 12 gets fuel out of the tank 14 provided. Conversely, the high-pressure pump feeds 12 Fuel in the common rail injection system 16 a, over which the injectors 18 of the injection system 16 be fueled.

The fuel distribution system 10 also has a return system 20 on, over the excess fuel back into the tank 14 is directed. Among other things, the returned fuel originates from the flange bearing 22 the high pressure pump 12 , the housing bearing 24 the high pressure pump 12 and a differential pressure valve 26 ,

The differential pressure valve 26 serves to equalize the pressure between a pump room 28 the high pressure pump 12 and the low pressure system 20 and opens when the pressure in the pump room 28 exceeds a predetermined pressure.

2 shows a three-dimensional view of holes in the interior of a pump housing 30 the pump 12 , In the 2 are a valve carrier bore 32 or piston bore 32 which has a valve inlet at one end 34 includes a hole 36 that have a valve outlet 38 includes, a return bore 40 for the flange bearing 22 , a return bore 42 for the housing bearing 24 and a return bore 44 for the pump interior 28 to recognize. The return bore 44 is over another hole 46 with the valve carrier bore 32 connected. The holes 36 . 32 and 46 extend coaxially, each having a smaller diameter than the previous bore.

The differential pressure valve 26 includes a piston 48 in the valve carrier hole 32 is guided sealingly and in a closed position of the differential pressure valve 26 on a heel 50 between the holes 32 . 46 is supported.

On another paragraph 52 between the holes 36 . 32 is a spring plate 54 supported, with the piston 48 a spring chamber 56 in the valve carrier bore 32 defined in which a compression spring 58 is included. The spring plate 54 closes the valve carrier bore 32 in the direction of the input bore 36 , This results in a closed spring chamber 56 , The feather 58 is at one end over a lead 60 on the spring plate 54 pushed and is located with another end in a cavity 62 in the piston 48 ,

In the hole 36 there is a return pipe connection 63 who has the spring plate 54 holds in place and to the end of the hole 36 on the stop surface or the paragraph 52 stuck.

The housing 30 from the 2 is in the 3 and 4 shown in further perspectives. At the end of the starting hole 36 there is an annular groove 64 around the valve carrier hole 32 runs around and into the return bore 42 empties. Parallel to the valve carrier bore 32 run in pairs four connection holes 66 which also in the annular groove 64 lead and the spring chamber 56 decouple. The ring groove 64 can be used as a distributor opening for distributing the out of the holes 42 . 66 originating fuel in the direction of the output bore 36 standing on the ring groove 64 is understood, understood.

As in the 5 and 6 shown below, the spring plate 54 at the radial height of the annular groove 64 three long holes 68 on, through which the fuel from the annular groove 64 into the starting hole 36 can flow.

In the in the 2 to 4 The embodiment shown is the return bore 40 with its end through the valve carrier bore 32 guided so that the connection holes 66 be cut and thus the connection holes 66 over the return bore 40 with the valve carrier bore 32 are connected. The return bore, for example, orthogonal to the valve carrier bore 32 run.

In the closed position, the valve piston closes 48 the openings formed thereby 70 in the wall of the valve carrier bore 32 , In the open position gives the piston 48 these openings 70 free, allowing fuel from the input bore 46 in the connection holes 66 can flow.

The openings 70 make a control edge with its edge 72 of the differential pressure valve 26 ready. The further the piston 48 the openings are released, the more disturbed fuel can enter the connection bores 66 parallel to the valve carrier bore 32 reach. The return flow then flows through the slots 68 of the spring plate 54 in the return pipe 63 ,

In the 5 become the components 63 . 54 . 58 . 48 of the differential pressure valve 26 shown in the holes 36 . 32 in the case 30 be attached.

In the 6 is a spring plate 54 shown. The spring plate 54 may be a disk-shaped body having a projection in the middle 60 which serves to fix the end of a spring. In the circumferential direction is the projection 60 of three kidney-shaped oblong holes 68 surround. In the center of the spring plate 60 may be a throttle opening 71 through which a small amount of fuel can flow. The in the spring plate 54 integrated throttle 71 can dampen the piston movement.

In the 7 is a piston 48 shown. The piston can be a cylindrical wall 73 exhibit that in the middle of a middle wall 74 into two (possibly equal) chambers 62 is divided. One of the chambers serves to receive one end of the spring 58 , For example, in the center of the middle wall may be a throttle opening 76 which have a connection between the input bore 46 and spring chamber 56 creates.

In the in the 8th to 10 In the embodiment shown, the return bore opens 40 in the return bore 42 going directly into the exit opening 36 (or the annular groove 64 ) opens. The valve carrier bore 32 has an undercut on its inside 80 on, which has such a large outside diameter that he has the connection holes 66 touches on.

Analogous to the openings 70 represents the undercut 80 a connection between the valve carrier bore 32 and the connection holes 66 ready by the piston 48 can be closed and opened.

The control edge 72 of the differential pressure valve is in this case of the undercut 80 provided.

This is schematically in the 11 shown the valve carrier bore 32 and an undercut 80a in the form of a continuous annular groove 80a from above and from the side shows. The ring groove 80a surrounds the valve carrier bore 32 in the entire circumferential direction and has in the opening direction 82 of the differential pressure valve 26 (parallel to the centerline or axis of the valve carrier bore 32 runs) a constant diameter.

In the 12 to 15 are further embodiments of undercuts 80b to 80e shown.

An annular groove 80b surrounds the valve carrier bore 32 in the entire circumferential direction and tapers in the opening direction.

An annular groove 80c surrounds the valve carrier bore 32 in the entire circumferential direction and widens in the opening direction.

An undercut 80d is in the circumferential direction around the valve carrier bore 32 segmented and can as a section annular groove 80d be understood.

An annular groove 80e surrounds the valve carrier bore 32 in the entire circumferential direction, but runs in contrast to those in the 11 to 14 shown embodiments not in a plane orthogonal to the opening direction 82 but obliquely to this plane.

In addition, it should be noted that "encompassing" does not exclude other elements or steps, and "a" or "an" does not exclude a multitude. It should also be appreciated that features or steps described with reference to any of the above embodiments may also be used in combination with other features or steps of other embodiments described above. Reference signs in the claims are not to be considered as limiting.

Claims (12)

Casing ( 30 ) for a high pressure pump ( 12 ) for conveying fuel, the housing ( 30 ) comprising: a pump room ( 28 ) inside the housing ( 30 ), in which the fuel is compressed, a differential pressure valve ( 26 ) with a piston ( 48 ) in a valve carrier of the differential pressure valve ( 26 ), wherein the differential pressure valve ( 26 ) is executed, a valve input ( 34 ) with a valve outlet ( 38 ) when the piston ( 48 ) is acted upon by a predetermined pressure, characterized in that the valve carrier as a bore ( 32 ) in the housing ( 30 ) is executed. Casing ( 30 ) according to claim 1, further comprising: at least one connecting bore ( 66 ), which the valve input ( 34 ) with the valve outlet ( 36 ) connects. Casing ( 30 ) according to claim 2, wherein the connecting bore ( 66 ) parallel to the valve carrier bore ( 32 ) runs. Casing ( 30 ) according to claim 2 or 3, wherein the connecting bore ( 66 ) via a return bore ( 40 ) with the valve carrier bore ( 32 ) connected is. Casing ( 30 ) according to one of the preceding claims, wherein a control edge ( 72 ) of the differential pressure valve ( 26 ) by an undercut ( 80 ) in the valve carrier bore ( 32 ) is formed. Casing ( 30 ) according to claim 5, wherein the undercut has an annular groove ( 80a . 80b . 80c . 80d . 80e ), and / or wherein the annular groove ( 80b . 80c . 80e ) an oblique to the valve carrier bore ( 32 ) extending side wall, and / or wherein the annular groove ( 80d ) in the circumferential direction around the valve carrier bore ( 32 ) is segmented, and / or wherein the annular groove ( 80e ) obliquely to the valve carrier bore ( 32 ) runs. Casing ( 30 ) according to one of the preceding claims, wherein the valve outlet ( 38 ) as a bore ( 36 ) which is coaxial with the valve carrier bore ( 32 ) is executed. Casing ( 30 ) according to one of the preceding claims, further comprising: a spring ( 58 ) and a spring plate ( 54 ), the spring ( 58 ) at one end on the valve piston ( 48 ) and on another side of the spring plate ( 54 ) is supported, wherein the spring plate ( 54 ) at the end of a bore ( 36 ) for the valve outlet ( 38 ), wherein the spring plate ( 54 ) by one in the valve outlet ( 38 ) ( 63 ) on the valve carrier bore ( 32 ) is clamped. Casing ( 30 ) according to claim 8, wherein the spring plate ( 54 ) has a throttle opening ( 71 ), the valve output ( 38 ) with a spring chamber ( 56 ), and / or wherein the piston ( 48 ) a throttle opening ( 76 ), which the spring space ( 56 ) with the valve inlet ( 34 ) connects. Casing ( 30 ) according to any one of the preceding claims, wherein the piston ( 48 ) as a hollow cylinder ( 73 ) with a middle wall ( 74 ) is executed. High pressure pump ( 12 ) with a housing ( 30 ) according to one of claims 1 to 10. A fuel delivery system for a vehicle, the fuel delivery system comprising: a tank ( 14 ), a high pressure pump ( 12 ) according to claim 11, a common rail injection system ( 16 ), the high-pressure pump ( 12 ) is designed to remove fuel from the tank ( 14 ) and the common-rail injection system ( 16 ), wherein the differential pressure valve ( 26 ) of the high-pressure pump ( 12 ) excess fuel from the high-pressure pump ( 12 ) in the tank ( 14 ).

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